Recently, silicon photonics foundries started providing access to new dielectric stacks which can be utilized to reduce optical I/O losses. For example, in a hybrid c-Si/SiN platform, inverse design techniques can be used to create novel dual layer grating coupler (GC) designs which, in simulations, reach state-of-the-art performance. In this paper, we experimentally validate such designs for perfectly vertical single-polarization GCs in the O-band consisting of a single-etch c-Si layer with a patterned SiN overlay, fabricated using a 193nm DUV immersion lithography process on 300mm wafers. Here, we investigate designs generated by two different design paradigms: inverse design based on the adjoint method and adjoint-inspired design. Using wafer-level testing, we experimentally demonstrate a record low median insertion loss (IL) of 1.3 dB (with interquartile range of ∼ 0.1 − 0.2 dB) for perfectly vertical coupling in DUV lithography compatible devices which is a ∼ 0.5 dB improvement over previously demonstrated single-layer, single-etch c-Si 0 deg GCs.